1. Goto, T, Kubota, Y, Toyoda, A. Effects of diet quality on vulnerability to mild subchronic social defeat stress in mice. Nutr Neurosci. 2016;19:284-289.
Google Scholar | Crossref | Medline2. Goto, T, Tomonaga, S, Toyoda, A. Effects of diet quality and psychosocial stress on the metabolic profiles of mice. J Proteome Res. 2017;16:1857-1867.
Google Scholar | Crossref | Medline3. Sato, M, Okuno, A, Suzuki, K, et al. Dietary intake of the citrus flavonoid hesperidin affects stress-resilience and brain kynurenine levels in a subchronic and mild social defeat stress model in mice. Biosci Biotechnol Biochem. 2019;83:1756-1765.
Google Scholar | Crossref | Medline4. Reeves, PG, Nielsen, FH, Fahey, GC. AIN-93 purified diets for laboratory rodents: final report of the American Institute of Nutrition ad hoc writing committee on the reformulation of the AIN-76A rodent diet. J Nutr. 1993;123:1939-1951.
Google Scholar | Crossref | Medline | ISI5. Miura, H, Ozaki, N, Sawada, M, Isobe, K, Ohta, T, Nagatsu, T. A link between stress and depression: shifts in the balance between the kynurenine and serotonin pathways of tryptophan metabolism and the etiology and pathophysiology of depression. Stress. 2008;11:198-209.
Google Scholar | Crossref | Medline | ISI6. Ye, Z, Yue, L, Shi, J, Shao, M, Wu, T. Role of IDO and TDO in cancers and related diseases and the therapeutic implications. J Cancer. 2019;10:2771-2782.
Google Scholar | Crossref | Medline7. Agudelo, LZ, Ferreira, DMS, Dadvar, S, et al. Skeletal muscle PGC-1α1 reroutes kynurenine metabolism to increase energy efficiency and fatigue-resistance. Nat Commun. 2019;10:2767.
Google Scholar | Crossref | Medline8. Agudelo, LZ, Ferreira, DMS, Cervenka, I, et al. Kynurenic acid and Gpr35 regulate adipose tissue energy homeostasis and inflammation. Cell Metab. 2018;27:378-392.e5.
Google Scholar | Crossref | Medline9. Okuno, A, Fukuwatari, T, Shibata, K. High tryptophan diet reduces extracellular dopamine release via kynurenic acid production in rat striatum. J Neurochem. 2011;118:796-805.
Google Scholar | Crossref | Medline | ISI10. Namikawa-Kanai, H, Miyazaki, T, Matsubara, T, et al. Comparison of the amino acid profile between the nontumor and tumor regions in patients with lung cancer. Am J Cancer Res. 2020;10:2145-2159.
Google Scholar | Medline11. Miyazaki, T, Nagasaka, H, Komatsu, H, et al. Serum amino acid profiling in citrin-deficient children exhibiting normal liver function during the apparently healthy period. JIMD Rep. 2019;43:53-61.
Google Scholar | Crossref | Medline12. Kimura, M, Yamamoto, T, Yamaguchi, S. A personal computer-based system for interpretation of gas chromatography mass spectrometry data in the diagnosis of organic acidaemias. Ann Clin Biochem. 1999;36:671-672.
Google Scholar | SAGE Journals | ISI13. Kimura, M, Yamamoto, T, Yamaguchi, S. Automated metabolic profiling and interpretation of GC/MS data for organic acidemia screening: a personal computer-based system. Tohoku J Exp Med. 1999;188:317-334.
Google Scholar | Crossref | Medline14. Benjamini, Y, Hochberg, Y. Controlling the false discovery rate: a practical and powerful approach to multiple testing. J R Stat Soc Ser B. 1995;57:289-300.
Google Scholar | Crossref15. Sekine, A, Kuroki, Y, Urata, T, Mori, N, Fukuwatari, T. Inhibition of large neutral amino acid transporters suppresses kynurenic acid production via inhibition of kynurenine uptake in rodent brain. Neurochem Res. 2016;41:2256-2266.
Google Scholar | Crossref | Medline16. Walker, AK, Wing, EE, Banks, WA, Dantzer, R. Leucine competes with kynurenine for blood-to-brain transport and prevents lipopolysaccharide-induced depression-like behavior in mice. Mol Psychiatry. 2019;24:1523-1532.
Google Scholar | Crossref | Medline17. Fukuwatari, T. Possibility of amino acid treatment to prevent the psychiatric disorders via modulation of the production of tryptophan metabolite kynurenic acid. Nutrients. 2020;12:1403.
Google Scholar | Crossref | Medline18. Toyoda, A, Shimonishi, H, Sato, M, Usuda, K, Ohsawa, N, Nagaoka, K. Effects of non-purified and semi-purified commercial diets on behaviors, plasma corticosterone levels, and cecum microbiome in C57BL/6J mice. Neurosci Lett. 2018;670:36-40.
Google Scholar | Crossref | Medline19. Pellizzon, MA, Ricci, MR. Effects of rodent diet choice and fiber type on data interpretation of gut microbiome and metabolic disease research. Curr Protoc Toxicol. 2018;77:e55.
Google Scholar | Crossref | Medline20. Klurfeld, DM, Gregory, JF, Fiorotto, ML. Should the AIN-93 rodent diet formulas be revised? J Nutr. 2021;151:1380-1382.
Google Scholar | Crossref | Medline21. Zhang, JC, Yao, W, Hashimoto, K. Brain-derived neurotrophic factor (BDNF)-TrkB signaling in inflammation-related depression and potential therapeutic targets. Curr Neuropharmacol. 2016;14:721-731.
Google Scholar | Crossref | Medline22. Garrison, AM, Parrott, JM, Tuñon, A, Delgado, J, Redus, L, O’Connor, JC. Kynurenine pathway metabolic balance influences microglia activity: targeting kynurenine monooxygenase to dampen neuroinflammation. Psychoneuroendocrinology. 2018;94:1-10.
Google Scholar | Crossref | Medline23. Fukui, S, Schwarcz, R, Rapoport, SI, Takada, Y, Smith, QR. Blood-brain barrier transport of kynurenines: implications for brain synthesis and metabolism. J Neurochem. 1991;56:2007-2017.
Google Scholar | Crossref | Medline | ISI24. Agudelo, LZ, Femenía, T, Orhan, F, et al. Skeletal muscle PGC-1α1 modulates kynurenine metabolism and mediates resilience to stress-induced depression. Cell. 2014;159:33-45.
Google Scholar | Crossref | Medline | ISI25. Joisten, N, Kummerhoff, F, Koliamitra, C, et al. Exercise and the Kynurenine pathway: current state of knowledge and results from a randomized cross-over study comparing acute effects of endurance and resistance training. Exerc Immunol Rev. 2020;26:24-42.
Google Scholar | Medline26. Okuno, A, Fukuwatari, T, Shibata, K. Urinary excretory ratio of anthranilic acid/kynurenic acid as an index of the tolerable amount of tryptophan. Biosci Biotechnol Biochem. 2008;72:1667-1672.
Google Scholar | Crossref | Medline | ISI27. Shibata, K, Matsuo, H. Effect of dietary tryptophan levels on the urinary excretion of nicotinamide and its metabolites in rats fed a niacin-free diet or a constant total protein level. J Nutr. 1990;120:1191-1197.
Google Scholar | Crossref | Medline | ISI28. Shibata, K. Relationship between urinary excretion of kynurenic acid and protein intake in rats. Agric Biol Chem. 1990;54:1591-1593.
Google Scholar29. Tanabe, A, Egashira, Y, Fukuoka, S, Shibata, K, Sanada, H. Expression of rat hepatic 2-amino-3-carboxymuconate-6-semialdehyde decarboxylase is affected by a high protein diet and by streptozotocin-induced diabetes. J Nutr. 2002;132:1153-1159.
Google Scholar | Crossref | Medline | ISI30. Egashira, Y, Yamamiya, Y, Sanada, H. Effects of various dietary fatty acids on α-amino-β-carboxymuconate-ε-semialdehyde decarboxylase activity in rat liver. Biosci Biotechnol Biochem. 1992;56:2015-2019.
Google Scholar | Crossref31. Owen, OE, Kalhan, SC, Hanson, RW. The key role of anaplerosis and cataplerosis for citric acid cycle function. J Biol Chem. 2002;277:30409-30412.
Google Scholar | Crossref | Medline | ISI32. Martin, DB, Vagelos, PR. The mechanism of tricarboxylic acid cycle regulation of fatty acid synthesis. J Biol Chem. 1962;237:1787-1792.
Google Scholar | Crossref | Medline33. Lillefosse, HH, Clausen, MR, Yde, CC, et al. Urinary loss of tricarboxylic acid cycle intermediates as revealed by metabolomics studies: an underlying mechanism to reduce lipid accretion by whey protein ingestion? J Proteome Res. 2014;13:2560-2570.
Google Scholar | Crossref | Medline34. Li, B, Sui, L. Metabolic reprogramming in cervical cancer and metabolomics perspectives. Nutr Metab. 2021;18:93.
Google Scholar | Crossref